Chiral amines thiourea

Some bifunctional hydrogen-bond donor/Brpnsted base catalysts are shown in Figures 2.39 and 2.40. They comprise chiral amino alcohols and amino phenols, chiral amine-thiourea derivatives, and chiral guanidines, among others. In the absence of detailed experimental NMR or kinetic studies [179], most of our... 

In addition, various chiral amine-thioureas have been successfully applied to promote asymmetric Mannich reactions. As an example, Takemoto and Miyabe have employed a chiral bifunctional organocatalyst possessing a thiourea moiety and a tertiary amino group as catalyst of the Mannich reaction between ethyl malonate and A-Boc arylimines, which provided the corresponding products in excellent yields and enantioselectivities (93-98% ee), as shown in Scheme S.lb. The degree of enantioselectivity was shown to be dependent on the reaction temperature, with the best results obtained at low temperature. 

Chiral amines and diamines are readily available substrates for the synthesis of ligands for transition metal-catalysed reactions since they can easily be transformed into chiral ureas and thioureas. Therefore, several groups have prepared chiral symmetrical ureas and thioureas, dissymmetrical ureas and thioureas, amino-urea and thiourea derivatives. Finally polyureas and non-soluble polythioureas were also prepared and tested as ligands for asymmetric catalysis. 

Treatment of a chiral amine with phosgene is the cheapest way to prepare symmetrical ureas [29]. Nevertheless, due to the toxicity and reactivity of that reagent, it can advantageously be replaced by triphosgene [30] or l,l -carbonyldiimidazole [31-34] or other derivatives such as l,l -carbonyldi-2(lH)-pyridinone [35]. This procedure can be extended to thiophosgene (Scheme 1) and its thio-analogues, such as l,l -thiocarbonyldi-2(lH)-pyridinone to produce thioureas [36] chiral diamines can thus be transformed into the corresponding monoureas or monothioureas. 

Since chiral amines are much more available than chiral isocyanates, ureas have often been obtained from reaction of an amine used as the chiral source with a stoichiometric amount of a non-chiral isocyanate [41]. Similarly, thioureas are obtained by reacting isothiocyanates with amines. The corresponding ureas and thioureas (examples in the following sections) are... 

Scheme 6.55 Design principle of amine-functionalized bifunctional thiourea organocatalysts derived from privileged monofunctional thiourea 9 cooperating with an amine base additive (A) and basic bifunctional mode of action of chiral amine...

Figure 6.18 Chiral amine 56 and thiourea derivatives (10mol% loading) screened in the asymmetric Michael addition of diethyl malonate to trcms-P-nitrostyrene in toluene.

The highly enantioselective direct conjugate addition of ketones to nitroalkenes has been promoted by a chiral primary amine-thiourea catalyst (7).31 The observed anti diastereoselectivity has suggested participation of a (Z)-enamine intermediate, given (g) the complementary diastereoselectivity obtained in analogous reactions involving (E)-enamines generated from secondary amine catalysts. 

Cyclohexanediamine-derived amine thiourea 70, which provided high enantio-selectivities for the Michael addition [77] and aza-Henry reactions [78], showed poor activity in the MBH reaction. This fact is not surprising when one considers that a chiral urea catalyst functions by fundamentally different stereoinduction mechanisms in the MBH reaction, and in the activation of related imine substrates in Mannich or Streclcer reactions [80]. In contrast, the binaph-thylamine thiourea 71 mediated the addition of dihydrocinnamaldehyde 74 to cyclohexenone 75 in high yield (83%) and enantioselectivity (71% ee) (Table 5.6, entry 2) [79]. The more bulky diethyl analogue 72 displayed similar enantioselectivity (73% ee) while affording a lower yield (56%, entry 3). Catalyst 73 showed only low catalytic activity in the MBH reaction (18%, entry 4). 

Table 5.6 The chiral tertiary amine/thiourea-catalyzed MBH reaction of dihydrocinnamaldehyde with cyclohexenone.

Disubstituted thiochroman-4-ols are formed with excellent enantio- and diastereo-selectivity when thiosalicylaldehydes react with an a,P-unsaturated oxazolidinone in the presence of a chiral bifunctional amine-thiourea catalyst. A tandem Michael - aldol process is involved (Scheme 43) <07JA1036>. 

A more simple thiourea catalyst with amino functionality catalyses the asymmetric Michael addition of 1,3-dicarbonyl compound to nitroolefin [29,30]. In the reaction of malonate to nitrostyrene (Table 9.11) the adduct is satisfactorily obtained when A-[3,5-bis(trifluor-omethyl)phenyl]-A -(2-dimethylaminocyclohexyl)thiourea is used as a catalyst (ran 1), whereas the reaction proceeds slowly when the 2-amino group is lacking (ran2). In addition, chiral amine without a thiourea moiety gives a poor yield and enantioselectivity of the product (run 3). These facts clearly show that both thiourea and amino functionalities are necessary for rate acceleration and asymmetric induction, suggesting that the catalyst simultaneously activates substrate and nucleophile as a bifunctional catalyst. 

Chiral bifunctional primary amine-thiourea/ f-BuNH2.TFA/DCM/25 °C (09MI1) 12/EtOH/rt (09MI2)... 

There is an interesting variant of this reaction which involves the use of tert-butyldimethylsilyloxyacetaldehyde as Michael donors and chiral primary amine thiourea bifunctional catalyst 37b (Scheme 2.13). In this case, the diastereoselectivity of the reaction changed from the usually observed syn relative stereochemistry at the final Michael adduct to the formation of the anti diastereoisomer as the major product. This change in diastereoselectivity was explained in terms of the generation of a Z-enamine intermediate assisted by the formation of an intramolecular hydrogen bond between the secondary... 

Axial-to-central chirality transfer in cyclization processes 13CSR8434. Bifunctional primary amine-thioureas in asymmetric organocatalysis 13OBC7051. 

Using the bifunctional chiral primary amine thiourea catalyst 41 (20 mol%) in CH Clj and in the presence of five equivalents of H O as additive, a highly enanti-oselective direct conjugate addition of a wide range of a,a-unsymmetrically dis-ubstituted aldehydes (only a twofold excess of aldehyde relative to nitroaUcene) to nitroolefins is obtained (see Table 2.1, entry 15, for a representative example) [61], The beneficial role of water is proposed to lie in increasing turnover by eliminating potential catalyst deactivation pathways, and accelerating the final imine hydrolysis. 

Scheme 2.41 Jacobsen s chiral primary amine-thiourea addition of ketones to nitroalkenes...

On the other hand, chiral primary amine-thiourea catalysts 85 and 90 developed by Tsogoeva [125] and Jacobsen [130], respectively, show an opposite sense of relative stereoinduction in the conjugate addition of acyclic ketones to nitroolefins (see Scheme 2.41 for 90). These anti selective catalysts stand in contrast to the usually obtained results which lead to selective formation of the i yn-conflgured diastereoiso-mers. The unexpected situation suggests participation of a Z-enamine intermediate. Moreover, with respect to the electrophile activation by the urea-type catalysts, it is also demonstrated that only one oxygen of the nitro group is bound to the thiourea moiety in an out-of-plane arrangement [125,130]. 

A highly enantioselective conjugate addition of nitromethane and nitroethane to acyclic enones has been recently achieved using chiral cyclohexanediamine-derived primary amine thiourea 48 (Scheme 2.57) [168], With respect to the electrophile, the reaction shows a broad substrate scope and not only 1-aryl- but also 1-alkyl enones afford the corresponding chiral y-nitroketones with good yields and excellent enantioselectivities (92-99% ee). 

Anthrones [204] and 3-substituted oxindoles [205] possess activated methylenes which have been able to react under asymmetric iminium catalysis with a,p-unsaturated aldehydes. The reaction with 3-substituted oxindoles is especially attractive, since chiral quaternary stereocenters are generated. For this purpose, chiral primary amine thiourea catalyst 132 has been demonstrated as a very efficient promoter for the addition of 3-alkyl substituted oxindoles to P-aryl substituted enals in the presence of benzoic acid as cocatalyst in toluene at rt to afford the corresponding Michael adducts in good diastereoselectivities (dr up to >19/1) and good enantioselectivities (73-93% ee) (Scheme 2.75) [205a], P-Alkyl substituted enals are not suitable partners for the reaction affording very low diastereo- and enanti-... 

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